Brake power booster



March 14, 1961 R. c. RIKE BRAKE POWER BOOSTER 3 Sheets-Sheet 1 Original Filed July 9, 1953 INVENTOR.

6'. Rike Attorney His Richard March 14, 1961 R. c. RlKE BRAKE POWER BOOSTER 3 Sheets-Sheet 2 Original Filed July 9, 1953 INVENTOR.

' Richard C. Hike His. Afjfar ney March 14, 1961 R. c. RIKE BRAKE POWER BOOSTER Original Filed July 9, 1953' 3 Sheets-Sheet 3 INVENTOR.

Richard C. Rike BY His Artemis-y U iwdS es Pa q iQ tors Corporation, Detroit, Mich.,'a corporation of Delaware Original application July 9, 1953, Ser. No. 366,891,

now Patent No. 2,887,848, dated May 26, 1959. Divided and this application Sept. 8, 1958, Ser. No. 759,476

6 Claims. (Cl. Gil-54.6)

This invention relates to a power unit for automotive hydraulic brakes adapted for providing the major portion of the braking eifort required for an automotive vehicle.

This is a division of application S.N. 366,891, Richard C. Rike', filed July 9, 1953 now Patent No. 2,887,848.

An object of the invention is to provide an improved power unit for use in an automotive hydraulic brake system wherein the power unit and the master cylinder are arranged as a unitary structure.

It is another object of the invention to provide a power unit having a pressure-differential operated motorthat power actuates a tubular piston within a master cylinder in cooperation with a reaction rod that slidably extends through the tubular piston into the master..cylinder, the reaction rod being operated in response to manual :actu-z ation of the reaction rod and the tubular piston providing the means for creating fluid pressure in the master cylinder in cooperation with the reaction rod.

1 It is still another-object of the invention to provide a powerunit'for an automotive hydraulic brakesystem utilizing a presSuredifle'rential operated motor that in torporates an improved poppet valve stru'cture forcom trolling. application of. negative pressure to one side of the-power piston of-the' power uni i I". 1' It-is still another object :ofthe invention toprovide 'a power. .unit for v an automotive..hydraulic'brake. system utilizing a pressure differential motor that efiects actuatibn of a pistomwithin a master cylinder, an improved seal structurebeing provided between the piston and the master cylinder to prevent leakage of hydraulic fluid from the master cylinder into the power motor.

It is another object of the invention to provide an improved power unit for a hydraulic brake system utilizing a pressure difi'erential operated motor wherein the structures of the motor are coaxially arranged and are prevented from relative rotation by means of spring anchors provided at each end of the compression spring that positions the. power piston at one end of the power cylinder.

Further objects and advantages of the present invention will be apparent from the following description, reference being had to the accompanying drawings wherein a preferred form of the invention is clearly shown.

- In the drawings:

Figure 1 is a longitudinal cross sectional view taken along line 1-1 of Figure 8 of a power unit incorporating features of this invention.

Figure 2 is. a cross sectional view taken along line 2-2 of Figure 1.

Patented Mar. 14, 1961 Figure 3 is an end view of the device illustrated in Figure 1, as viewed from the left hand end thereof.

Figure 4 is a cross sectional view through the power cylinder illustrating the manner of sealing the air inlet and vacuum connections for the unit.

Figure 5 is an enlarged cross sectional view of the master cylinder.

Figure 6 is a cross sectional view taken along line 6-6 of Figure 5.

Figure 7 is a cross sectional view taken along line 7-7 of Figure 5.

Figure 8 is a transverse cross sectional view taken along line 8- 8 of Figure 1.

Figure 9 is a cross sectional view through the master cylinder taken long line 99 of Figure 1.

Figure 10 is a schematic illustration of a hydraulic connection provided between a manually operated pedal and the power unit for remote manual response of the power unit.

In this invention the power unit consists of a pressure differential operated motor 10 that consists of a cylinder 11 and a power piston 12 reciprocal within the cylinder 11. A master cylinder 15 is attached to one end of the power cylinder 11 and provides the pressure fluid for supply to the brake system of a motor vehicle.

- The power piston 12 actuates a tubular piston 16 that has one end thereof projecting into the master cylinder 15. A reaction rod or central piston 17 is slidable within the'tubular piston 16 andalso enters the master cylinder 15, whereby-the coaction of the reaction rod 17 and the tubular piston 16 effect application of pres sure on the liquid in the master cylinder 15 to supply hydraulic fluid under pressure to the brake system of k the motor vehicle.

Fluid under pressure is discharged from the master cylinder 15 through a discharge opening 18 and a check valve 20 into the pressure line 21. The pressure line 21 connects with wheel cylinders 22 provided in the brakes 23 for? each of the wheels of the motor vehicle.

The. power piston 12 is actuated by operation of a control-valve 25Jadapted to control the connection of one side of the power piston 12 with a source of negative pressure, such as the vacuum'manifold of an internal com The valve 25 is operated by a valve actuator 26 that is responsive to operation of a manually operated brake pedal 27. The brake pedal 27 is connected through a pedal push rod 28 with the reaction rod 17 for causing operation of the valve actuator 26.

Operation of the brake pedal 27 will thus cause manual operation of the reaction rod 17 which in turn effects operation of the valve 25 to. render active the power piston 12. The power piston 12 moves the tubular piston 16 thereby giving concurrent movement to the reaction rod 17 and the tubular piston 16 for causing pressure upon the fluid in the master cylinder 15 and supply of the same to the brake cylinders 22 of the I wheels of the motor vehicle.

The pressure differential operated motor 10 comprises the cylinder housing 11 forming the cylinder of the motor. One end of the cylinder 11 is closed by the closure member 29 that is secured to the cylinder 11 through the flanged portions 30 and 31 that are secured together by the arrangement of the bolt 32 and nut 33 extending through the respective flanges. A gasket 34 sealsv the.

cylinder includes a housing 35 that is secured to the cylinder 11 by means of suitable bolts 36.

The power piston 12 divides the cylinder 11 into two chambers 37 and 38, the chamber 38 being continuously in connection with atmospheric pressure through the air inlet pipe 39, see Figures 3 and 4. A suitable air filter is provided on the air inlet .pipe 39 to prevent entry of dirt into the chamber 38.

The power piston 12 carries the' tubular piston 16 that has an enlarged head 40 at one end thereof that is received within the recess 41 provided in the body of the piston 12. The head 40 is retained within the recess 41 by a retaining cap 42, see Figures 1 and 8. A rubberlike seal member 43 is placed in a recess 44 provided in the head 40 on the piston 16. This rubber-like seal member 43 is retained in the recess 44 by a closure member 45. The seal member 43 being substantially U- shaped in transverse cross section will thus engage the outer wall of the recess wall 44 and the outer periphery of the reaction rod 17 to seal upon the same and thereby prevent leakage of fluid under pressure between the reaction rod or central piston 17 and the tubular piston 16. An 0 ring seal member 49 is retained in a recess 57 in the head 40 to seal against leakage between the head 40 and the recess 41. v i

The power piston 12 is normally spring urged to the position shown in Figure 1 by means of the compression spring 50 that has one end thereof engaging an end wall of the cylinder 11 and the opposite end engaging the inner face of the piston 12. The spring 50 has an inwardly turned end 51 positioned substantially radial of the axis of the spring for engaging one of the.bolts 36 that secures the master cylinder housing 35 to the cylinder 11. The opposite end of the spring 50 has an inwardly turned end 52 substantially radial of the axis of the spring that is adapted to rest between a pair of the raised lugs 53 provided on the inner face of the piston 12, as shown in Figures 1 and 8. The spring having each of its ends engaging a fixed portion on the wall of the cylinder 11 'and the piston 12 thereby prevents rotation of the piston relative to they cylinder, and of the several parts carried thereby. H

,The tubular piston 16 carried by the power piston 12 enters the master cylinder 15 through a seal member This seal 60 for the master cylinder 15 comprises a cylin der shell 55 that is slidable within a chamber 56 provided in the housing 35. The shell 55 has a coaxial recess 51 in which a rubber-like seal 58 is positioned. The seal 58 engages the outer periphery of the tubular piston 16 and also engages the outer wall of the recess 57 to seal: against loss of fluid pressure within the master cylinder 15. An annular recess 59 is provided in the outer periphcry of the shell 55 for. connecting with a passage 61.that extends between the recess 57 and the recess 59. A passage 62 connects the recess 59 with the chamber 63 that is connected to a fluid reservoir 64 through a passage 65 in a fitting 66 placed in the closure nut 67 that is in threaded engagement with a threaded portion 68 of the chamber 63.

The seal 60 in the master cylinder 15 includes an an nular disc 70 that has a clearance passage 71 around the outer periphery of the tubular piston, 16 and has' longiw The disc 70 is positioned? tudinal passages 72 therein. against the shoulder 73 provided between the recess 57 and the larger recess 74 that is provided forwardly of the;

recess 57.

A spacer sleeve 75 is positioned between the disc 70 and the seal member 58 to retain the seal in position in the recess 57 without applying any pressure upon the seal member.

Forwardly of the disc 70 there is provided a. secondseal member for sealing .between'the forwardend of, the tubular piston 16 and the peripheral wall of the recess 74. The seal 80 is retained in position by a metal bearing member 81 having one end thereof engaging the seal 80 and the opposite end engaging a snap ring 82 that retains the bearing member 81 in position within the recess 74 and also retains the seal assembly in assembled condition.

The seal member 80 is provided with a plurality of resilient ribs 83 on the forward face thereof that are engaged by the rear face of the bearing member 81 to take up manufacturing tolerances between the bearing member 81 and the seal 80 without causing any substantial pressure on the seal member 80.

The bearing sleeve 81 engages the outer periphery of the tubular piston 16 and forms thereby a bearing for the tubular piston in its reciprocal motion through the seal 60 into and out of the master cylinder 15.

The outer periphery of the bearing member 81 is provided with a series of flutes or passages 85. The outer periphery of the seal member 80 is provided with a relieved portion that forms a chamber 86 between the seal 80 and the wall of the recess 74, see Figure 5. The seal member however normally closes the passage 72 in the disc 70 to prevent flow of fluid under pressure through the passage 70 in a leftward direction, as viewed in Figures l and 5. However, fluid from the reservoir 64 can pass through the passage 72, the chamber 86, past the. peripheral lip 87 on the seal 80 and through the passages in the bearing member 81 into the master cylinder 15 during a retraction movement of the pistons 16 and 17 to prevent a vacuum from developing in the master cylinder during a fast return stroke of the pistons 16.and 11. 9 When the piston 16 is in the position illustrated in Figures 1 and 5, a vent passage 88 in the forward end 1 of the piston 16 communicates with a chamber 89 provided between the seal 80 and the forward end of the piston 16 whereby fluid within the master cylinder can flow into the reservoir through the passage 88, the passage 71 and through the holes 90' provided in the F sleeve 75 to the reservoir passages 61, 62, and 65.

The master cylinder 15 is provided with a check valve 20, see Figure 9, for controlling flow of fluid to and from the pressure line 21 for the brake system. This check valve 20 comprises a cap or hat-like member 91 that is held on a rubber-like seat member 92 by means of a compression spring 93. A rubber-like disc member 94 isplaced on the underside of the cap member 91 and covers ,the openings 95 in the member 91'against flow of fluid in a leftward direction, as viewed in Figure 9.

The disc-like member 94 is retained in position by a retaining member 96 that has passages 97 at the periphery thereof.

The discharge opening 18 from the master cylinder 15. connectswith the check valve chamber 98 and the passage 99 in the fitting 100 connects with the pressure ine 21.

The check valve 20 is thus of a construction whereby fluid under pressure can flow freely from the master cylinder 15 through the check valve 20 and into the pressure line 21. When pressure is released on the fluid in the master cylinder 15 the return flow of fluid will be required to lift the hat-like member 91 from the seat 92 against the 'action of the spring 93 so as to insure a positive minimum pressure being retained in the pressure line-21 at all times to prevent air leakage into the wheel cylinders 22 of the brakes.

The power piston 12 has a cup seal 101 at the periphery thereof retained on the piston by a retaining member 102. A radially expanding leaf type spring 103 urges the lip of the cup seal 101 against the inner periphery of the cylinder 11, a felt annular ring 104 being adapted to supply a slight amount of lubricant to the cup seal 101 and thereby lubricate the bearing surface between the cup seal'and the bearing 11.

The po wer piston 12 contains the control valve 25' Within a chamber 105 provided in the wall of the piston '12. The chamber 105 has a'connecting chamber passage 106 having a seat 107 around the periphery thereof upon which the valve element 108 seats as retained thereby by a compression spring 109 vpositioned between the valve element 108 and the closure plate 110 for the chamber 105.

The chamber 105 connects with a source of. negative pressure through a passage 111 that connects with. a second passage 1'12 extending forwardly to the forward face 113 of the piston 12. The passage 112 receives one end of a pipe 114 that has a flexible conduit 115 secured on the free end thereof. The flexible conduit 115 encircles the axis 'offithe chamber 38, as shown in Figure 3 and connects: with a pipe 116 that passes through a seal member 117 provided in the wall 'of the chamber 38. The pipe 116 is connected with the intake manifold of a motor vehicle to provide the suitable sourceof negative pressure for supply to the chamber 105 in the piston 12.

A passage 118 is provided in the piston 12 for connection of the chamber passage 106 with the chamber 37 in the cylinder 11 whereby the pressure conditions in the chamber 37 can be changed from one of a positive pressure to one of a negative pressure under control of the actuation of the control valve 25.

The control valve 25 is operated by the valve actuator 26 that consists of a hollow cylinder 120 slidable in a bearing sleeve 121 provided in the piston 12. The internal bore 122 provides connection between the chamber 38 and the chamber passage 106 to provide for connection of the chamber 37 with the atmospheric'pressure continuously existing in the chamber 38 through the bore 122, the chamber passage 106 and the passage 118.

The valve actuator 26 is carried upon a rigid member 125 that projects from a plunger member 126 slidable in the bore 127 provided in the piston 12 coaxially of the reaction rod 17. The member 126 is retained between an annular head 128 on a plunger member 126 and a snap ring 129 on the plunger member 126.

The plunger member 126 encircles the reaction rod 17 and is slidab'le thereon, but is limited in its sliding movement and is carried with the reaction rod through a snap ring 130 on the reaction rod 17. A compression spring 135 is positioned between the piston 12 and the member 125 to normally retain the hollow cylinder 120 of the valve actuator 26in spaced relationship to the valve element 25, as illustrated in Figure l, to thereby normally supply atmospheric pressure to both sides of the power piston 12 so that the compression spring 50 will position the piston 12 as illustrated in Figure l.

The plunger member 126 is retained in the bore 127 against removal therefrom by the action of the oompres si-on spring 135 by a stop bracket 136 having itsopposite ends fastened to the piston 12 by means of bolts 137, as illustrated in Figure 2. p

The pedal push rod '28 is enclosed with a flexible rubber-like boot 140 that has one end thereof secured to the closure member 29 by a retaining member 141 and the opposite end enclosing the pedal push rod as illustrated at 142. v

In operation, when the brake pedal 27 ismoved down wardly, the pedal rod 28 is moved in right-hand direction, as viewed in Figure 1. Initial movement of the pedal rod 28 causes advancement of the reaction rod or central piston 17 as well as the plunger 126 and the cylinder 122 of the valve actuator 26. At this time no braking action develops because the vent 88' in the tubular piston 16 is connected to the reservoir. When sufficient forward movement is given to the pedal rod 28 and the plunger 126 to cause the forward end of the member 122 to close upon the valve element 108, positive pressure from the chamber 38 to the chamber 37 through the valve actuator 26 is thereby cut off. 'A slight additional movement of the pedal rod 28, and thus the valve actuator cylinder 122 causes the valve element 108 to lift from the seat 107 and thereby connect the source of negative pressure in the chamber with the chamber 37 through the passages 106 and 118.

When the chamber 37 is connected with the source of negative pressure, the chamber is evacuated. Thus, atmospheric. pressure standing against the left hand face of the piston 12 causes movement of the piston 12 ina right hand direction against the compression spring 50.

So long as the forward advancement of the pedal rod 28 and the piston 12 are exactly the same, pressure will be continuously applied to the liquid in the master cylinder 15 by simultaneous movement of the tubular piston 16 and the. reaction rod or central piston 17. Fluid under pressure will be delivered to the brake cylinders 22 to apply the brakes.

However, should the action of atmospheric pressure on the piston 12 cause the piston to move more rapidly leftwardly than the rate of forward advancement of the pedal rod 28, or should the operator stop downward movement of the brake pedal, thus halting forward movement of the pedal rod 28, the piston 12 will advance just sufficiently to allow the valve element 108 to seat upon the seat 107 and thereby cut off connection between the chamber 37 and the source of negative pressure in the chamber 105. Slight additional movement of the piston 12 at this time will move the valve element 108 away from the end of the cylinder 122 of the valve actuator 26 thereby again allowing atmospheric pressure to be delivered from the chamber 38 to the chamber 37 through the valve actuator and the passages 106 and 11's. I

By the foregoing operation it will be understood that the movement of the power piston 12 will exactly follow the advancement of the pedal rod 28, and thus respond exactly to the braking action applied by the operator to the brake pedal 27. I

When brake action is to be released, and the brake pedal 27 is allowed to move upwardly, thus causing retraction movement of the pedal rod 28, the actuator cylinder 122 will be withdrawn from engagement with the valve element 108 to allow it to seat upon the seat 107 to cut off the source of negative pressure in the chamber 105 from the chamber 37. Introduction of atmospheric pressure into the chamber 37 through the valve actuator cylinder 122 allows the spring 50 to be: come effective to move the piston 12 in a left hand direction, as viewed in Fig. l.

Retraction movement of the piston 12 will cause the tubular piston 16 to be retracted by engagement of the element 42 with the head 40 on the tubular pistonto move it in a left hand direction. Also, with thepiston 12 moving in a left hand direction, the plunger 126 will engage the snap ring on the reaction rod 17- to cause its retraction movement. This will continue until such time as the resilient rubber pad 145 on the bracket 1'36 engages the closure plate 29 to stop movement of the power piston and elements carried thereby.

In Figure 10 there is illustrated a slightly modified arrangement of manual actuating means for causing movement of the pedal push rod 28 of the power unit 10. In this arrangement the brake pedal 27a operates a piston 'reciprocal in a cylinder 151. The cylinder 151 is fluid connected with a cylinder 152 through a conduit 153. The cylinder 152 has a piston 154 that connects on the end of the pedal push rod 28a. 1

The fluid system is supplied with fluid from the reservoir 155 to take up any leakage in the system.

A spring 156 in the cylinder 152 normally urges re.-

turn of the pedal push rod 28a to its starting position.

It will be understood that downward movement of the brake pedal 27a causes movement of the piston 150 within the cylinder 151 to thereby transfer fluid from this cylinder to the cylinder 152 and thereby cause move- 7 ment of the piston 154 and resulting in operation of the pedal push rod 28a in the same manner as heretofore described. 7

Thus, the system illustrated in Figure 10 provides for remote positioning of the power unit relative to the brake pedal.

While the form of embodiment of the invention as herein disclosed constitutes a preferred form, it is to be understood that other forms might be adopted as may come within the scope of the claims which follow.

What is claimed is as follows:

1. In an automotive brake operating mechanism, a pressure differential operated motor including a cylinder and a. power piston therein, a master cylinder, piston means extending from said power piston into said master cylinder for efiecting compression of liquid in said master cylinder, a seal means between said piston means and said master cylinder comprising, a housing member in said cylinder and removable from said cylinder, said housing having a transverse wall with a concentric opening for receiving said piston means, a first resilient seal between said piston means and said housing member seated on said transverse wall, a removable rigid wall positioned transversely of said housing and through which said piston means extends forwardly into said master cylinder, a spacing sleeve between said first seal and said removable wall and engaging each, a second resilient seal between said piston means and said housing and engaging said removable wall, and a rigid bearing member positioned forwardly of said second seal relative to the interior of the cylinder and engaging the second seal and engaging said. piston means to retain said second seal in position in said housing against said wall and provide a bearing means for said piston means. 7

2. In an automotive brake operating mechanism, a pressure differential operated motor including a cylinder and a power piston therein, a master cylinder, piston means extending from said power piston into said master cylinder for effecting compression of liquid in said master cylinder, a seal means between said piston means and said master cylinder comprising, a housing member having a transverse wall with a central opening for receiving said piston means, said housing member mounted in said cylinder and removable from the cylinder, a first resilient seal between said piston means and said housing member being seated on said transversehousing wall, a second wall positioned transversely in said housing and through which said piston means extends forwardly into said master cylinder, a spacing sleeve between said first seal and said second wall and engaging each, a second resilient seal between said piston means and siad housing and engaging said second wall, and a rigid bearing member positioned forwardly of said second seal relative to the interior of the cylinder and engaging the second seal and engaging said piston means to retain said second seal in position in said housing and provide a bearing means for said piston means, said bearing member having passage means on the periphery thereof to allow liquid flow into said master cylinder from between said first and second seals through passage means provided in said .wall and around the periphery of said second seal.

3. In an automobile brake operating mechanism, a means of operating a fluid displacement member, a master cylinder, said fluid displacement member extending from said operating means into said master cylinder for effecting compression of liquid within said master cylinder, a chamber adjacent said master cylinder for reception of a sealing means comprising a housing member, a bearing member mounted in said housing member having a central opening to receive said fluid displacement member, a rubber seal rearward of and adjacent to said bearing member, said rubber seal mounted adjacent to an annular disc having a central opening for reception of said fluid displacement member, said annular disc having longitudinal holes angularly spaced about said central opening, said annular disc mounted on a shoulder portion of said housing member, a second seal mounted rearward of said first mentioned seal, said second seal disposed within and for sealing of the inner periphery of said housing member and the outer periphery of said fluid displacement member, said second seal held in posi-' tion by a retainer sleeve abutting a groove portion in said second seal and extending forward to said annular disc, thereby providing two concentric seals on said fluid displacement member to provide sealing means for said master cylinder and said fluid displacement member.

4. man automotive brake mechanism, manual means for operating a master piston means, a master cylinder, said piston means extending into said master cylinder for effecting compression of liquid in said master cylinder, a concentric chamber adjacent to and concentric with said master cylinder, said chamber containing seal means comprising, a housing member, a bearing member within said housing member for receiving said piston means, a seal mounted adjacent to and concentric with said bearing member, said seal mounted within the inner periphery of said housing member and slidably engaging the outer periphery of said piston means, said rubber seal engaging an annular disc having a central hole for receiving said piston means and angularly spaced holes radially spaced from said central hole, said annular disc mounted on a shoulder portion of said housing member, a second seal mounted in said housing member, said second seal having a groove portion on the forward side for engaging a retainer sleeve, said retainer sleeve mounted within said grooved portion of said second seal and spaced between said seal and said annular disc, said seal means thereby providing a double seal for said piston means contained in a unit assembly.

5. In an automotive brake operating mechanism, a master cylinder, 21 fluid reservoir in communication with said master cylinder, piston means extending into said master cylinder for effecting compression of liquid within said master cylinder, means for actuating said piston means, a chamber in communication with said master cylinder for receiving a seal means comprising in combination, a housing means, a bearing member received in said housing means and retained in position by a snap ring, said bearing member having fluted portions on its outer periphery where said bearing member engages inner periphery of said housing member, a seal member mounted concentric with said bearing member and having fluted portions on the forward side of said seal member, said fluted portions on said seal member in communication with the fluted portion of said bearing member, said seal member mounted adjacent to and engaging an annular disc on the rearward end of said seal member, said annular disc provided with a central opening for receiving said piston means, a plurality of holes in said annular disc, a second seal member mounted concentric with said first mentioned seal member, said second seal member having a central groove, said groove portion of said second seal engaging a retainer sleeve disposed between said seal and said annular disc, said sleeve provided with radial holes to provide communication from the outer periphery of said piston means to a reservoir, said fluted portions of said bearing member and said fluted portions of said first seal member being in communication with said master cylinder to provide a vacuum relief for the outer periphery of said first mentioned seal upon rearward movement of said piston means.

6. In an automotive brake operating mechanism, a master cylinder mounted adjacent to and in communication with a fluid reservoir, piston means extending into said master cylinder for effecting compression of liquid in said master cylinder, means for actuating said piston means, a seal means in said master cylinder including a housing member, a piston bearing member mounted within said housing member for receiving said piston means within a central opening, a seal mounted concentrically within said housing adjacent to said bearing member and slidably engaging said piston means on the inner periphery of said seal, said seal abutting an annular disc mounted in the rearward side of said seal, said annular disc having a central opening for receiving said piston means, said annular disc having holes on a common radial circle, a second seal mounted rearward of said first mentioned seal for receiving said piston means, said second seal having a groove for reception of a retainer sleeve, said retainer sleeve disposed between said second seal and said annular disc, passage means from the outer periphery of said piston means to said fluid reservoir, second passage means from said reservoir extending through said annular disc about the outer periphery of said first mentioned seal to relieve any vacuum about the outer periphery of said first mentioned seal upon rearward movement of said piston 5 means.

References Cited in the file of this patent UNITED STATES PATENTS 

